Cyclic 3'', 5''-AMP relay in dictyostelium discoideum. IV. Recovery of the cAMP signaling response after adaptation to cAMP

In dictyoselium discoideum, an increase in extracellular cAMP activates adenylate cyclase, leading to an increase in intracellular cAMP and the rate of cAMP secretion. Cells adapt to any constant cAMP stimulus after several minutes, but still respond to an increase in the concentration of the stimulus. We have now characterized the decay of adaptation (deadaptation) after the removal of cAMP stimuli. Levels of adaptation were established by the perfusion of [(3)H]adenosine-labeled amoebae with a defined cAMP stimulus. After a variable recovery period, the magnitude of the signaling response to a second stimulus was measured; its attenuation was taken as a measure of residual adaption to the first stimulus. The level of adaptation established by the first stimulus depended on both its magnitude and duration. Deadaptation began as soon as the first stimulus was removed. The magnitude of the response to the second stimulus increased with the recovery time in a first-order fashion, with a t(1/2)=3-4 min for stimuli of 10(-8) M to 10(-5) M cAMP. Responses to test stimuli, although reduced in magnitude, had an accelerated time-course when they closely followed a prior response that had not completely subsided. This effect is called priming; we believe it reveals a reversible, rate-limiting step that modulates the onset and termination of the signaling responses of amoebae that have not recently responded to a cAMP stimulus. We have suggested that the cAMP signaling response is controlled by two antagonistic cellular processes, excitation and adaptation. The data reported here imply that both the rate of rise in the adaptation process and the final level reached depend on the occupancy of cAMP surface receptors and that the decay of adaptation when external cAMP is removed proceeds with first-order kinetics.     

Cyclic 3'',5''-AMP relay in Dictyostelium discoideum III. The relationship of cAMP synthesis and secretion during the cAMP signaling response

Refinement of a perfusion technique permitted the simultaneous measurement of cAMP-elicited [3H]cAMP secretion and intracellular [3H]cAMP levels in sensitive D. discoideum amoebae. These data were compared with measurements of the rate of [32P]cAMP synthesis by extracts of amoebae sonicated at different times during the cAMP signaling response. cAMP stimulation of intact cells led to a transient activation of adenylate cyclase, which was blocked if 10(-4) M NaN3 was added with the stimulus. During responses elicited by 10(-6) M cAMP, 10(-8) M cAMP, and an increment in cAMP from 10(-8) M to 10(-7) M, the rate of cAMP secretion was proportional to the intracellular cAMP concentration. Removal of a 10(-6) M cAMP stimulus 2 min after the initiation of the response led to a precipitous decline in intracellular cAMP. This decline was more rapid than could be accounted for by secretion alone, suggesting intracellular phosphodiesterase destruction of newly synthesized cAMP. Employing these data and a simple rate equation, estimates of the time-course of the transient activation of adenylate cyclase and the rate constants for cAMP secretion and intracellular phosphodiesterase activity were obtained. The calculated rate of cAMP synthesis rose for approximately 1 to 2 min, peaked, and declined to approach prestimulus levels after 3 to 4 min. This time-course agreed qualitatively with direct measurements of the time-course of activation, indicating that the activation of adenylate cyclase is a major in determining the time-course of the cAMP secretion response.     

Cyclic 3'', 5''-AMP relay in Dictyostelium discoideum: adaptation is independent of activation of adenylate cyclase

In Dictyostelium discoideum, binding of cAMP to high affinity surface receptors leads to a rapid activation of adenylate cyclase followed by subsequent adaptation within several minutes. The rate of secretion of [ 3H ]cAMP, which reflects the state of activation of the enzyme, was measured. Caffeine noncompetitively inhibited the response to cAMP. Inhibition was rapidly reversible and pretreatment of cells with caffeine for up to 22 min had little effect on the subsequent responsiveness to cAMP. However, cells pretreated with caffeine plus cAMP for greater than or equal to 8 min did not respond when caffeine was removed and the same concentration of cAMP was applied. The following observations indicate that both adaptation and deadaptation to cAMP occurred to the same extent and at the same rate whether or not cAMP synthesis was inhibited. First, when cells were pretreated with 10(-9)-10(-6) M cAMP in the presence or absence of caffeine and the stimulus was switched to a saturating dose of cAMP, the response to the increment was the same whether or not the initial response was blocked. Second, cells progressively lost responsiveness to 10(-6) M cAMP as pretreatment with 10(-6) M cAMP plus caffeine was extended from 0 to 8 min with the same time course as for those pretreated with 10(-6) M cAMP alone. Third, cells which were adapted in the presence of caffeine and cAMP deadapted within the same time period as controls when cAMP was removed. These observations demonstrate that while some part of the activation process is inhibited by caffeine the adaptation process is unaffected. Our conclusion is that adaptation does not depend on the activation of adenylate cyclase.     

Calcitonin gene-related peptide stimulates intracellular cAMP via a protein kinase C-controlled mechanism in human ocular ciliary epithelial cells.

Calcitonin gene-related peptides I and II (CGRP I and II) were found to stimulate cAMP levels by approximately 4-6 fold in human nonpigmented ciliary epithelial cells with half-maximal effective concentrations of 20 x 10(-10) and 3 x 10(-10) M, respectively. Prior exposure of cells to 6 x 10(-7) M phorbol 12-myristate, 13-acetate for 15 min resulted in a 40-50% inhibition of CGRP II-dependent cAMP stimulation. Phorbol didecanoate and dioctanoylglycerol also effectively inhibited, whereas 4 alpha phorbol didecanoate, an ineffective activator of protein kinase C, had no effect. Staurosporine, a protein kinase C inhibitor, blocked the inhibition of cAMP formation by phorbol esters. cAMP stimulation by forskolin or cholera toxin was not inhibited by phorbol esters, suggesting that neither a Gs protein nor adenylyl cyclase is the site of inhibition by protein kinase C. These data therefore suggest that CGRP receptors are required for inhibition of adenylate cyclase by protein kinase C.     

MCH-induced pigment aggregation in teleost melanophores is associated with a cAMP reduction.

It has previously been shown that alpha 2-adrenoceptors are involved in noradrenaline-induced pigment aggregation within fish melanophores. In the present investigation, melanin concentrating hormone (MCH) elicited pigment aggregation (EC50 approximately 1 x 10(-7) M) that was associated with a significant reduction in the cAMP content; 1 x 10(-7) M MCH reduced the cAMP content from a basal level of 50.4 +/- 2.8 pmol/mg protein to 36.9 +/- 3.8 pmol/mg protein. Like the alpha 2-adrenoceptor-induced pigment aggregation, the MCH response was effectively blocked by the adenylate cyclase stimulator forskolin. These findings suggest that attenuation of cAMP may serve as an intracellular signal transduction mechanism for both MCH and noradrenaline.     

Inhibition of basal and hormone-stimulated adenylate cyclase in adipocyte ghosts by the prostaglandin endoperoxide prostaglandin H2.

The prostaglandin endoperoxide PGH2 (15-hydroxy-9alpha, 11alpha-peroxidoprosta-5,13-dienoic acid), at a concentration of 2.8 x 10(-5) M inhibited basal adenylate cyclase activity 11% and epinephrine-stimulated activity 30 to 35%. PGH2 inhibited epinephrine-stimulated enzyme activity in the presence of 10 mM theophylline, 2.5 mM adenosine 3':5'-monophosphate (cAMP), or in the absence of inhibitors or substrates of the cAMP phosphodiesterase. When the cAMP phosphodiesterase was assayed directly using 62 nM and 1.1 muM cAMP, PGH2 did not affect the 100,000 x g particulate cAMP phosphodiesterase from fat cells. The inhibition of adenylate cyclase by PGH2 was readily reversible. A 6-min preincubation of ghost membranes with PGH2, followed by washing, did not alter subsequent epinephrine-stimulated adenylate cyclase activity. During epinephrine stimulation, the PGH2 inhibition was apparent on initial rates of cAMP synthesis, and the addition of PGH2 to the enzyme system at any point during an assay markedly reduced the rate of cAMP synthesis. Between 2.8 x 10(-7) M and 2.8 x 10(-5) M, PGH2 inhibited epinephrine-stimulated enzyme activity in a concentration-dependent manner. The stimulation of adenylate cyclase by thyroid-stimulating hormone, glucagon, and adrenocorticotropic hormone as well as by epinephrine was antagonized by PGH2, suggesting that PGH2 may be an endogenous feedback regulator of hormone-stimulated lipolysis in adipose tissue.     

Adaptation in the motility response to cAMP in Dictyostelium discoideum

When developing amebae of Dictyostelium discoideum are treated with constant concentrations of cAMP above 10(-8)M, the average rate of motility is depressed, with maximum inhibition at roughly 10(-6)M. It is demonstrated that shifting the concentration of cAMP from 0 M to concentrations ranging from 10(-8) to 10(-6)M in a perfusion chamber results in the immediate inhibition of motility. After shifting from 0 M to 10(-8) or 10(-7)M, the rate of cell motility remains low, then rebounds to a higher level, exhibiting a standard adaptation response. No adaptation is exhibited after a shift from 0 M to 10(-6)M, a concentration resulting in maximum inhibition. It is demonstrated that the level of inhibition and the extent of the adaptation period are dependent upon the concentration of cAMP after the shift, and that submaximal inhibition is additive. The characteristics of adaptation in this motility response are very similar to the characteristics of adaptation for the relay system and phosphorylation of the putative cAMP receptor.     

Differential effects of temperature on cAMP-induced excitation, adaptation, and deadaptation of adenylate and guanylate cyclase in Dictyostelium discoideum

Extracellular cAMP induces excitation of adenylate and guanylate cyclase in Dictyostelium discoideum. Continuous stimulation with cAMP leads to adaptation, while cells deadapt upon removal of the cAMP stimulus. Excitation of guanylate cyclase by cAMP has a lag time of approximately 1 s; excitation of adenylate cyclase is much slower with a lag time of 30 s. Excitation of both enzyme activities is less than twofold slower at 0 degrees C than at 20 degrees C. Adaptation of guanylate cyclase is very fast (t1/2 = 2.4 s at 20 degrees C), and virtually absent at 0 degrees C. Adaptation of adenylate cyclase is much slower (t1/2 = 110 s at 20 degrees C) but not very temperature sensitive (t1/2 = 290 s at 0 degrees C). At 20 degrees C, deadaptation of adenylate cyclase is about twofold slower than deadaptation of guanylate cyclase (t1/2 = 190 and 95 s, respectively). Deadaptation of adenylate cyclase is absent at 0 degrees C, while that of guanylate cyclase proceeds slowly (t1/2 = 975 s). The results show that excitation, adaptation, and deadaptation of guanylate cyclase have different kinetics and temperature sensitivities than those of adenylate cyclase, and therefore are probably independent processes.     

Surface receptor-mediated activation of adenylate cyclase in Dictyostelium. Regulation by guanine nucleotides in wild-type cells and aggregation deficient mutants

GTP and GTP analogs produced significant (up to 17-fold) and persistent activation of adenylate cyclase in lysates of Dictyostelium discoideum amoeba. The activation was enhanced 2- to 4-fold by cAMP (the agonist for receptor-mediated adenylate cyclase activation), was specific for guanine nucleoside triphosphates, and was inhibited by guanosine 5'-(O-2-thio)diphosphate. The order of potency of guanine nucleotides was guanosine 5'-(O-3-thio)triphosphate greater than guanyl-5'-yl imidodiphosphate greater than GTP; half-maximal activation was observed with 1-10 microM guanine nucleotide. Maximal activation occurred when the guanine nucleotide was added within seconds after cell lysis and the lysate was preincubated for 5 min prior to assay. Under these optimal in vitro conditions, the capacity of guanine nucleotides to activate decreased, closely correlating with adaptation or desensitization induced by exposure of intact cells to cAMP during a period of 10 min. These data strongly support that regulation of adenylate cyclase in Dictyostelium occurs via a receptor-linked GTP/GDP exchange protein. Two mutants, designated synag 7 and 49 were isolated in which cAMP and/or guanine nucleotides were not sufficient to activate adenylate cyclase. The wild-type pattern of guanine nucleotide regulation was restored to synag 7 lysates by the addition of a high-speed supernatant from wild-type cells. Characterization of these mutants demonstrates that activation of adenylate cyclase is not required for growth or cell-type specific differentiation but is essential for cellular aggregation and influences morphogenesis and pattern formation. This suggests that Dictyostelium may provide a model suitable for detailed genetic analysis of surface receptor-guanine nucleotide-binding regulatory protein linked adenylate cyclase systems and for determining the role of these systems in development.     

Regulation of adenylate cyclase in electropermeabilized Dictyostelium discoideum cells.

In Dictyostelium discoideum cells the enzyme adenylate cyclase is functionally coupled to cell surface receptors for cAMP. Coupling is known to involve one or more G-proteins. Receptor-mediated activation of adenylate cyclase is subject to adaptation. In this study we employ an electropermeabilized cell system to investigate regulation of D. discoideum adenylate cyclase. Conditions for selective permeabilization of the plasma membrane have been described by C.D. Schoen, J. C. Arents, T. Bruin, and R. Van Driel (1989, Exp. Cell Res. 181, 51-62). Only small pores are created in the membrane, allowing exchange of exclusively low molecular weight substances like nucleotides, and preventing the loss of macromolecules. Under these conditions functional protein-protein interactions are likely to remain intact. Adenylate cyclase in permeabilized cells was activated by the cAMP receptor agonist 2'-deoxy cAMP and by the nonhydrolyzable GTP-analogue GTP gamma S, which activates G-proteins. The time course of the adenylate cyclase reaction in permeabilized cells was similar to that of intact cells. Maximal adenylate cyclase activity was observed if cAMP receptor agonist or GTP-analogue was added just before cell permeabilization. If these activators were added after permeabilization adenylate cyclase was stimulated in a suboptimal way. The sensitivity of adenylate cyclase activity for receptor occupation was found to decay more rapidly than that for G-protein activation. Importantly, the adenylate cyclase reaction in permeabilized cells was subject to an adaptation-like process that was characterized by a time course similar to adaptation in vivo. In vitro adaptation was not affected by cAMP receptor agonists or by G-protein activation. Evidently electropermeabilized cells constitute an excellent system for investigating the positive and negative regulation of D. discoideum adenylate cyclase.     

Adenosine 3', 5'-monophosphorothioate (Rp-isomer) induces down-regulation of surface cyclic AMP receptors without receptor activation in Dictyostelium discoideum

cAMP induces the activation and subsequent desensitization of adenylate cyclase in Dictyostelium discoideum. cAMP also induces down-regulation of surface cAMP receptors. Desensitization of adenylate cyclase is composed of a rapidly reversible component (adaptation) and a slowly reversible component related to down-regulation of surface cAMP receptors (Van Haastert, P.J.M. (1987) J. Biol. Chem. 262, 7700-7704). The agonistic and antagonistic activities of the cAMP derivative adenosine 3',5'-monophosphorothioate ((Rp)-cAMPS) for these responses were investigated. (Rp)-cAMPS competes with cAMP for binding to different receptor forms with an apparent Ki = 5 microM. (Rp)-cAMPS does not activate adenylate cyclase and antagonizes the cAMP-induced activation with an apparent Ki = 5 microM. (Rp)-cAMPS induces down-regulation of surface cAMP receptors with EC50 = 5 microM. (Rp)-cAMPS induces desensitization of adenylate cyclase, which is not rapidly reversible. These results indicate that desensitization of adenylate cyclase by (Rp)-cAMPS is due to down-regulation of surface cAMP receptors and not to adaptation. We conclude that down-regulation of surface cAMP receptors does not require their activation or modification involved in adaptation.     

Adenosine and its derivatives inhibit the cAMP signaling response in Dictyostelium discoideum

In developmentally competent Dictyostelium discoideum amoebae, binding of cAMP to high-affinity surface receptors produces a rapid activation of adenylate cyclase which adapts within minutes. The result is a transient increase in intracellular cAMP which is rapidly secreted. Adenosine inhibited this cAMP signaling response with an apparent Ki of 300 microM. The apparent Ki's for 2'-O-methyladenosine and 2-chloroadenosine were approximately 30 and 100 microM, respectively. Inhibition by adenosine was rapid, reversible, and depended on the cAMP stimulus concentration. In addition, the adaptation of the cAMP signaling response was blocked by adenosine. As has been previously reported, adenosine inhibits cAMP binding to intact cells. Under the same developmental conditions as in the perfusion studies, we find the binding inhibition depends on both the cAMP and adenosine concentrations, with an apparent Ki of 100 microM. The apparent Ki's for 2'-O-methyl- and 2-chloroadenosine were approximately 8 and 35 microM, respectively. However, with cells developed for short times and with an axenic strain, inhibition was independent of cAMP concentration or cells showed mixed-type binding inhibition. The effect of adenosine on the cAMP signaling response is consistent with the reported effects of adenosine on other cAMP-mediated processes such as chemotaxis and the increase in intracellular cGMP, and may provide an explanation for the reported inhibition of center formation.     

Cellular responsiveness to cyclic AMP in a phosphodiesterase-defective mutant of Dictyostelium discoideum

Responsiveness of Dictyostelium discoideum amoebae to cAMP, a chemotactic mediator, was investigated in a strain defective in cAMP-phosphodiesterase production. Cells were subjected to a high cAMP signal (10(-6) M) in the presence or absence of exogenous phosphodiesterase, and the changes of intracellular cAMP and cGMP concentrations and of adenylate cyclase activity were measured. In the presence of cAMP hydrolysis, both adenylate and guanylate cyclases are transiently activated. In the absence of hydrolysis, the high and constant extracellular cAMP concentration is sufficient to elicit a re-activation of adenylate cyclase a few minutes after the first transient response. In contrast, levels of cGMP remain basal for at least 20 min after termination of the initial response to the cAMP addition.     

Multiple hormone actions: the rises in cAMP and Ca++ in MDCK-cells treated with glucagon and prostaglandin E1 are independent processes.

Glucagon and prostaglandin E1 stimulate adenylate cyclase in Madin-Darby canine kidney cells with an approximate EC50 of 3*10(-8) and 1*10(-7) M respectively. The rise in cAMP is accompanied by a transient rise in intracellular Ca++ measured with the fluorescent calcium indicator Indo-1. A comparable increase in intracellular Ca2+ without a rise in cAMP occurs with the cholinergic agonist carbamylcholine. Stimulation of adenylate cyclase by the beta-adrenergic agonist isoproterenol or directly by forskolin has no effect on intracellular Ca++. By all criteria studied the rise in intracellular Ca++ and the increase in cAMP are independent from each other.     

Down-regulation of cell surface cyclic AMP receptors and desensitization of cyclic AMP-stimulated adenylate cyclase by cyclic AMP in Dictyostelium discoideum. Kinetics and concentration dependence

cAMP binds to Dictyostelium discoideum surface receptors and induces a transient activation of adenylatecyclase, which is followed by desensitization. cAMP also induces a loss of detectable surface receptors (down-regulation). Cells were incubated with constant cAMP concentrations, washed free of cAMP, and cAMP binding to surface receptors and cAMP-induced activation of adenylate cyclase were measured. cAMP could induce maximally 65% loss of binding activity and complete desensitization of cAMP-stimulated adenylate cyclase activity. Half-maximal effects for down-regulation were observed at 50 nM cAMP and for desensitization at 5 nM cAMP. Down-regulation was rapid with half-times of 4, 2.5, and 1 min at 0.1, 1, and 10 microM cAMP, respectively. Similar kinetic data have been reported for desensitization (Dinauer, M.C., Steck, T.L., and Devreotes, P.N. (1980) J. Cell Biol. 86, 554-561). Down-regulation and desensitization were not reversible at 0 degrees C. Down-regulation reversed slowly at 20 degrees C with a half-time of about 1 h. Resensitization of adenylate cyclase was biphasic showing half-times of 4 min and about 1 h, respectively; the contribution of the rapidly resensitizing component was diminished when down-regulation of receptors was enhanced. These results suggest that cAMP-induced down-regulation of receptors and desensitization of adenylate cyclase stimulation proceed by at least two steps. One step is rapidly reversible, occurs at low cAMP concentrations, and induces desensitization without down-regulation, while the second step is slowly reversible, requires higher cAMP concentrations, and also induces down-regulation.     

Excitation, adaptation, and deadaptation of the cAMP-mediated cGMP response in Dictyostelium discoideum

Extracellular cAMP induces chemotaxis and cell aggregation in dictyostelium discoideum cells. cAMP added to a cell suspension is rapidly hydrolyzed (half-life of 10 s) and induces a rapid increase of intracellular cGMP levels, which reach a peak at 10 s and recover prestimulated levels at about 30 s. This recovery is not due to removal of the stimulus because the nonhydrolyzable analogue adenosine 3’,5’-monophosphorothioate-Sp- stereoisomer (cAMPS) induced a comparable cGMP response, which peaked at 10 s, even at subsaturating cAMPS concentrations. When cells were stimulated twice with the same cAMP concentration at a 30-s interval, only the first stimulus produced a cGMP response. Cells did respond to the second stimulus when the concentration of the second stimulus was higher than that of the first stimulus. By increasing the interval between two identical stimuli, the response to the second stimulus gradually increased. Recovery from the first stimulus showed first-order kinetics with a half-life of 1-2 min. The stimulation period was shortened by adding phosphodieterase to the cell suspension. The cGMP response was unaltered if the half-life of cAMP was reduced to 2 S. The peak of the transient cGMP accumulation still appeared at 10 s even when the half- life of cAMP was 0.4 s; however, the height of the cGMP peak was reduced. The cGMP response at 10 s after stimulation was diminished by 50 percent when the half-life of 10(-7) M cAMP was 0.5 s or when the half-life of 10(-8) M cAMP was 3.0 s. These results show that the cAMP signal is transduced to two opposing processes: excitation and adaptation. Within 10 s after addition of cAMP to a cell suspension the level of adaptation reaches the level of excitation, which causes the extinction of the transduction of the signal. Deadaptation starts as soon as the signal is removed, and it has first-order kinetics with a half-life of 1-2 min.     

cAMP induces a rapid and reversible modification of the chemotactic receptor in Dictyostelium discoideum

Stimulation, within 1 min after cAMP stimulation, of aggregation-competent Dictyostelium discoideum amebae was found to cause a rapid (within 1 min) modification of the cell's surface cAMP receptor. The modified receptor migrated on SDS PAGE as a 47,000-mol-wt protein, as opposed to a 45,000-mol-wt protein labeled on unstimulated cells. The length of time this modified receptor could be detected depended upon the strength of the cAMP stimulus: 3-4 min after treatment with 10(-7) M cAMP, cells no longer possessed the 47,000-mol-wt form of the cAMP receptor. Instead, the 45,000-mol-wt form was present. Stimulation of cells with 10(-5) M cAMP, however, resulted in the persistent (over 15 min) expression of the modified receptor. The time course, concentration dependence, and specificity of stimulus for this cAMP-induced shift in the cAMP receptor were found to parallel the cAMP-stimulated phosphorylation of a 47,000-mol-wt protein. In addition, both phenomena were shown to occur in the absence of endogenous cAMP synthesis. The possibility that the cAMP receptor is phosphorylated in response to cAMP stimulation, and the role of this event in cell desensitization, are discussed.     

Properties of the oscillatory cAMP binding component of Dictyostelium discoideum cells and isolated plasma membranes.

The cAMP receptor on the surface of aggregation competent Dictyostelium discoideum cells specifically binds [3H]cAMP in an oscillatory manner with a periodicity of 2 min. The oscillatory cAMP-binding component is developmentallly regulated and has the nucleotide specificity expected for recognition of chemotactic signals. The concentration dependence of the peak amplitudes of cAMP binding exhibit an apparent threshold at 10(-8) M cAMP. The threshold concentration for cAMP binding that we measure is consistent with the concentration dependence of signal relay (cAMP secretion) and the chemotactic response. The kinetic data of binding and dissociation are very rapid, consistent with the time course of oscillations in receptor capacity (affinity). Specific binding oscillations are destroyed by heat or chymotrypsin but are insensitive to trypsin or glycosidase. A plasma membrane localization of receptor is supported by enrichment of cAMP binding in a plasma membrane preparation from differentiated cells. Receptor oscillations with a 2-min period are preserved in the membrane preparations, and the peak amplitudes are increased about 10-fold consistent with the enrichment of other plasma membrane markers. The alternating change in the receptor's binding capacity for cAMP may be the basis of the relay refractory period as well as the primary oscillator involved in the generation of postreceptor events such as stimulation of adenylate cyclase, cAMP secretion, and cellular movement, all of which have been previously shown to oscillate.     

The specificity of the cAMP receptor mediating activation of adenylate cyclase in Dictyostelium discoideum

In Dictyostelium discoideum amoebae, binding of cyclic AMP (cAMP) to surface receptors elicits numerous responses including chemotaxis, cyclic GMP (cGMP) accumulation, and activation of adenylate cyclase. The specificity of the surface cAMP receptor which mediates activation of adenylate cyclase and cAMP secretion was determined by testing the relative effectiveness of a series of 10 cAMP analogs. Each of the 10 analogs elicited cAMP secretion, chemotaxis, and cGMP accumulation in the same dose range. The order of potency for eliciting these responses (cAMP greater than 2'-H-cAMP greater than N1-O-cAMP greater than cAMPS(Sp) greater than 6-Cl-cAMP greater than cAMPN(CH3)2(Sp) greater than 3'-NH-cAMP greater than 8-Br-cAMP greater than cAMPS(Rp) greater than cAMPN(CH3)2(Rp] matches that for binding to the major cell surface cAMP binding sites and differs from that of the cell surface phosphodiesterase and the major intracellular cAMP binding protein.     

Intracellular cAMP in Dictyostelium discoideum: Characterization of an aggregation-deficient mutant with elevated cAMP pools

Forty aggregation-deficient mutants of Dictyostelium discoideum were screened for changes in intracellular cAMP during the first 10 hr of starvation. The pools in 39 of the mutants remained low and relatively static during this period. However, amoebae of one mutant, strain HC151, exhibited significantly elevated levels of intracellular cAMP during vegetative growth and for several hours after starvation. A more detailed analysis of this mutant indicated that the elevated cAMP pools in these cells are a consequence of the premature appearance and partial activation of an adenylate cyclase. The mutation(s) altering adenylate cyclase regulation in this strain appears to map in linkage group IV. Complementation tests between strain HC151 and another mutant, HH201, which has recently been shown to produce an adenylate cyclase activity precociously [1], indicated that the mutations affecting adenylate cyclase activity in these strains map at different loci. Although both of these mutations behave recessively in heterozygous diploids with respect to gross development, an examination of early cAMP metabolism and terminal spore differentiation in these diploids suggest that these mutations are at least partially expressed during some stage(s) of the developmental cycle.